FIELD OF THE INVENTION
[0001] This invention relates to metabolic intervention with GLP-1 to therapeutically improve
the function of ischemic and reperfused tissue.
BACKGROUND OF THE INVENTION
[0002] Cellular damage to aerobic organ tissues is well recognized as a consequence of ischemia,
whether endogenous as in the case of a spontaneous coronary artery occlusion, or iatrogenic
such as with open heart, coronary bypass surgery, or transplant procedures with the
heart or other organs such as the lung, liver, kidney, pancreas and gastrointestinal
tract. The degree and duration of the ischemia causing events are relevant to the
amount of cell death and/or reversible cellular dysfunction. It is also known that
much of the tissue damage in fact occurs upon reperfusion (i.e., resumption of blood
flow) and re-oxygenation of the previously anoxic tissue. Reperfusion injury has been
the subject of considerable recent study prompted by medical advances particularly
in the treatment of reperfusion injury after myocardial infarction and other myocardial
remedial procedures such as coronary bypass, other open heart surgeries, as well as
organ transplants.
[0003] As a side product of normal aerobic respiration, electrons are routinely lost from
the mitochondrial electron transport chain. Such electrons can react with molecular
oxygen to generate the reactive free radical superoxide which through other reaction
steps in the presence of hydrogen peroxide and iron produces the extraordinarily reactive
and toxic hydroxyl radical. Metabolically active aerobic tissues possess defense mechanisms
dedicated to degrading toxic free radicals before these reactive oxygen species can
interact with cellular organelles, enzymes, or DNA, the consequences of which could,
without such protective mechanisms, be cell death. These defense mechanisms include
the enzymes superoxide dismutase (SOD) which disproportionates superoxide, catalase
which degrades hydrogen peroxide, and the peptide glutathione which is a non-specific
free radical scavenger.
[0004] While not fully understood, it is believed that with ischemia of metabolic tissues
and subsequent reperfusion, a complex group of events occurs. Initially during the
ischemic period, intracellular anti-oxidant enzyme activity appears to decrease, including
that of SOD, catalase, and glutathione. There is also an indication that the level
of xanthine oxidase activity concomitantly increases in vascular endothelial tissue
during the ischemic event. The combination of enhanced ability to produce oxygen free
radicals (via enhanced xanthine oxidase activity) and reduced ability to scavenge
the same oxygen radicals (via reduced SOD, catalase and glutathione activity) greatly
sensitizes the ischemic cell to an oxidative burst, and hence damage, should these
cells be subsequently reperfused with blood and therefore oxygen. This oxidative burst
occurring within seconds to minutes of reperfusion could result in reversible and
irreversible damage to endothelial cells and other cells constituting the ischemic-reperfused
organ matrix. If, for example, the heart is the organ under consideration, reversible
oxidative damage can contribute to myocardial stunning, whereas irreversible damage
presents itself as a myocardial infarction. Attendant with this initial oxidative
burst is oxidation damage to cell membranes. Lipid oxidation in cell membranes appears
to play a role in neutrophil chemotaxis to post-ischemic areas. Such activated neutrophils
adhere to vascular endothelium, induce the conversion of xanthine dehydrogenase to
xanthine oxidase within said endothelial cells, and further aggravate loss of endothelial
integrity. Activated neutrophils also migrate out of the vasculature into myocardial
interstitial spaces where the inflammatory cells can directly kill myocytes. Additionally,
perturbations in normal calcium mobilization from sarcoplasmic reticulum as a consequence
of ischemia-reperfusion contribute to reversible myocardial dysfunction referred to
as myocardial stunning.
[0005] The consequences of ischemia-reperfusion events are reversible and irreversible cell
damage, cell death, and decreased organ functional efficiency. More specifically,
in the case of myocardial reperfusion injury, the consequences include myocardial
stunning, arrhythmias, and infarction, and as a result, cariogenic shock and potentially
congestive heart failure.
[0006] The paradox of cellular damage associated with a limited period of ischemic anoxia
followed by reperfusion is that cell damage and death appear not only likely to directly
result from the period of oxygen deprivation but, additionally, as a consequence of
re-oxygenation of tissues rendered highly sensitive to oxidative damage during the
ischemic period. Reperfusion damage begins with the initial oxidative burst immediately
upon reflow and continues to worsen over a number of hours as inflammatory processes
develop in the same post-ischemic tissues. Efforts dedicated to decreasing sensitivity
of post-anoxic cells to oxidative damage and, additionally, efforts to reduce inflammatory
responses in these same tissues have been shown to reduce the reversible and irreversible
damage to post-anoxic reperfused organs. A combination of methods to reduce both the
initial oxidative burst and subsequent inflammation associated damage could provide
synergistic protection against reperfusion injury.
[0007] With respect to the treatment of ischemia coincident with MI patients, common therapies
now used are to employ thrombolytics such as streptokinase and t-PA and angioplasty.
U.S. Pat. No. 4,976,959 discloses the administration of t-PA and SOD to inhibit tissue
damage during reperfusion and/or percutaneous transluminal coronary angioplasty coincident
with ischemia to restore regional blood flow. Thus, an increasing number of patients
are being exposed to the likelihood of reperfusion injury and its effects, particularly
cardiac patients.
[0008] Reperfusion injury to organs other than the heart will generally manifest itself
in substantially reduced efficiency of function, a consequence of which may be premature
degeneration of the organ, or simply shutdown. Additionally, transplanted organs experience
enhanced rejection rates if there is significant underlying reperfusion injury.
[0009] As discussed briefly above, while the precise mechanism of reperfusion injury has
not been clearly defined, mounting data, most of which has been gathered in various
cardiac model studies, indicate that the generation of oxygen-derived free radicals,
including superoxide anion (O
2)
-, the hydroxyl free radical (.OH) and H
2O
2, results as a consequence of the reintroduction of molecular oxygen with reperfusion
and plays an important role in tissue necrosis. Agents which either decrease the production
of these oxygen derived free radicals (including allopurinol and deferroxamine) or
increase the degradation of these materials such as superoxide dismutase, catalase,
glutathione, and copper complexes, appear to limit infarct size and also may enhance
recovery of left ventricular function from cardiac stunning.
[0010] The use of metabolic intervention as a therapy specifically during acute myocardial
infarction is well established, although not without controversy. There is abundant
experimental and clinical evidence to support the use of a glucose-insulin-potassium
(GIK) infusion - the primary form of metabolic intervention - after acute MI, particularly
following the success of the Swedish DIGAMI study (MaZmberg, K, and DIGAMI Study Group
(1997) Prospective randomized study of intensive insulin treatment on long term survival
after acute myocardial infarction in patients with diabetes mellitus.
Brit. Med. J. 314, 1512-1515). The DIGAMI study emphasized the efficacy of a glucose-insulin infusion
for acute MI in diabetic patients, but this type of therapy has never been suggested
or used for reperfusion.
[0011] It therefore can be seen that there is a need for a safe effective composition having
broad applicability to prevent or ameliorate the harmful effects of ischemia and reperfusion
for tissues in general, especially organ tissue and, including but not limited to
myocardium. It is primary object of the present invention to fulfill this need.
[0012] Another object of the present invention is to provide a method for treating ischemia
and reperfusion without the side effects normally attendant with therapies presently
available,
[0013] Still another object ofthe present invention is to provide a pharmaceutically acceptable
carrier composition which can be used for intravenous administration of the compositions
of the present invention without any significant undesirable side effects and without
adversely affecting antigenic or immune stimulating properties.
[0014] These and other objects and benefits of the present invention will be apparent to
those skilled in the art from the further description and the accompanying claims.
[0015] In publication "Circulation vol. 98, 1998, pp. 2223-2226" the treatment of myocardial
infarctions with GIK (glucose-insulin-potassium) in the form of acute reperfusion
therapy is disclosed. International patent application No. WO 9808531 discloses the
possibility of substituting GIK with GLP-1 in the treatment of acute myocardial infarctions
(AMIs), however such treatment still requires the administration of glucose and even
potassium in some cases.
Summary of the Invention
[0016] The present invention provides for the use of a composition which includes GLP-1,
or a biologically active analogue thereof, and a pharmaceutically acceptable carrier,
for the manufacture of a medicament for treating individuals in need of amelioration
of organ tissue injury caused by reperfusion of blood flow following a period of ischemia,
said treatment does not include the co-administration of glucose.
DETAILED DESCRIPTION OF THE INVENTION
[0017] GLP-1 is a glucose-dependent insulinotropic hormone that effectively enhances peripheral
glucose uptake without inducing dangerous hypoglycemia. Further, GLP-1 strongly suppresses
glucagon secretion, independent of its insuliniotropic action, and thereby powerfully
reduces plasma free fatty acid (FFA) levels substantially more than can be accomplished
with insulin. High FFA levels have been implicated as a major toxic mechanism during
myocardial ischemia.
[0018] We have now developed the concept of GLP-1 as a metabolic therapy for ischemia-reperfusion
injury. This development was based on the realization that there are two clinical
situations in which ischemia-reperfusion is a routine, and potentially dangerous,
event: thrombolytic procedures for acute MI, and cardiac reperfusion following ischemic
cardioplegia during heart surgery. Moreover, recent experimental and clinical data
have established that the phenomenon of ischemia-reperfusion is particularly responsive
to metabolic therapy with GIK infusion, even more so than isolated ischemia without
reperfusion (Apstein, CS (1998) Glucose-insulin-potassium for acute myocardial infarction.
Remarkable results from a new prospective, randomized trial.
Circulation 98, 2223-2226).
[0019] The two most important therapeutic advances in the treatment of acute ischemia coincident
with MI in the past decade have been the introduction of thrombolysis and β-blockade.
However, despite this overall success, some studies of thrombolysis have revealed
an early excess mortality, which has been attributed to reperfusion-induced injury
and myocardial stunning. The mechanisms underlying stunning are complex, but an emerging
consensus is that this is likely related to intracellular acidosis leading to dysfunctional
sarcolemmal Ca
2+ pumps and cytosolic Ca
2+ overload. The net result is impaired myocardial contractile function leading to decreased
mechanical efficiency, as well as reperfusion ventricular arrhythmias. Moreover, recent
research has established that the intracellular acidosis, in turn, is due to an imbalance
between glycolysis and complete glucose oxidation, in the sense that the rate of glycolysis
is uncoupled from the oxidation of pyruvate (the end product of glycolysis) in the
TCA cycle. This uncoupling results in net H
+ production due to conversion of pyruvate to lactate. The most likely cause for this
imbalance is the presence of high plasma free fatty acid (FFA) levels, which preferentially
enter the mitochondria and inhibit pyruvate oxidation, a mechanism that elegantly
accounts for the well-established observation that hearts perfused with FFA are less
able to recover in the reperfusion phase than hearts perfused with glucose. It has
here been discovered, and is one of the bases of this therapeutic invention that GLP-1
suppresses FFA beyond what is expected with insulin which is at the 50% level of suppression,
and GLP-1 can be as high as 90% suppression of FFA.
[0020] These considerations have strengthened our conviction to treat ischemia-reperfusion
with glucagon-like peptides. It is well established that during normal perfusion and
adequate oxygenation, the heart depends on aerobic metabolism and uses FFAs as its
preferred fuel. In contrast, during ischemia (reduced blood flow) or hypoxica (reduced
O
2 tension), β-oxidation of fatty acids is impaired (because it is strictly aerobic)
and continued provision of ATP is dependent increasingly on anaerobic glycolysis.
During the ischemic period, glucose-insulin is of benefit because it enhances glucose
uptake and stimulates glycolysis, thereby providing ATP for maintenance of essential
membrane functions, especially ion transport. Moreover, glucose-insulin suppresses
adipose tissue lipolysis, thereby reducing plasma FFA levels and uptake of FFAs into
the myocardium. High levels of FFAs are toxic to the ischemic myocardium, both by
direct detergent effects on membranes and increases in cAMP, and by accumulation of
acylcamitine, which inhibits Ca
2+ pumps. The net effect is disturbance of ion exchange, cytosolic Ca
2+ overload, and resultant contractile dysfunction and arrhythmias.
[0021] During the reperfusion period, glucose-insulin is of benefit because, as explained
above, this therapy can alleviate the metabolic imbalance that produces stunning.
This is achieved by direct stimulation of PDH and hence pyruvate oxidation, and indirectly
by reduced FFA uptake and hence improved ratio of pyruvate to FFA oxidation.
[0022] From the above discussion it is evident that the dual action of glucose-insulin -
enhanced glucose uptake and metabolism, and reduced FFA levels - has substantial therapeutic
potential in reperfusion. Some have expressed a concern that during profound, essentially
zero-flow ischemia, glycolytic end products, namely lactate, will accumulate due to
inadequate "wash-out". Lactate accumulation, in turn, leads to high intracellular
proton concentrations, and failure to reoxidize NADH; high [H
+] and NADH/NAD
+ ratios inhibit productive glycolysis. Under these circumstances, glucose can be toxic
to cells, because ATP is actually consumed in the production of fructose-1,6-bisphosphate,
and high [H
+] can aggravate myocyte necrosis (Neely, JR, and Morgan, HE (1974) Relationship between
carbohydrate and lipid metabolism and the energy balance of heart muscle.
Ann. Rev. Physiol. 36,413-459). However, these concerns have not been borne out by the weight of experimental
and clinical data, which indicate that glucose-insulin produces beneficial results.
While not wishing to be bound by theory, the likely explanation for this is that in
humans, acute spontaneous ischemia is not a condition of zero-flow ischemia, but instead
represents a region of low-flow ischemia in which residual perfusion is adequate for
substrate delivery and lactate washout. This realization has now provided a powerful
physiological logic for the use of metabolic therapy in ischemia-reperfusion.
[0023] Modem cardiac surgery, whether involving cardiac valve replacement or coronary artery
bypass grafting (CABG), routinely requires hypothermic cardioplegic arrest, aortic
crossclamping, and cardiopulmonary bypass during surgery. Effectively, therefore,
routine cardiac surgery induces a state of elective global ischemia followed by reperfusion,
which potentially exposes the heart to all the attendant risks and injuries peculiar
to myocardial ischemia-reperfusion. Hence, prevention of myocardial damage during
and after cardiac operations remains a major concern. Elective cardioplegic ischemia
followed by reperfusion has obvious parallels with ischemia-reperfusion encountered
during acute MI followed by revascularization, and thus many of the pathophysiological
principles considered in previous sections also apply during cardiac surgery. However,
there are some notable differences between surgical cardioplegic ischemia-reperfusion
and MI-associated ischemia-reperfusion. During surgery, the heart is arrested (cardioplegia)
and infused with a cold (hypothermic) solution designed to optimize myocardial preservation.
After completion of the surgery, the heart is reactivated and reperfused with oxygenated
blood at body temperature. This produces a sequence of hypothermic ischemia and normothermic
reperfusion, which may prevent the accumulation of high tissue levels of H
+ and lactate. Moreover, unlike acute MI, hypothermic cardioplegia represents a state
of global, zero-flow ischemia, followed by global reperfusion.
[0024] In our previous application (Serial No. 60/103,498), of which this is a continuation-in-part,
we reviewed the disadvantages of glucose-insulin infusions and the advantages of substituting
these with a GLP-1 infusion, which is safer than insulin. In summary, GIK infusions
carry significant risks of both hypoglycemia and hyperglycemia, and are technically
demanding and staff-intensive. The dangers of hypoglycemia are obvious.
[0025] In contrast, these risks do not exist with a GLP-1 infusion. Glucagon-like peptide
(7-36) amide (GLP-1) is a natural, gut-derived, insulinotropic peptide that constitutes
a major component of the so-called incretin effect. GLP-1 exerts its major effect
at the pancreatic endocrine cells, where it (1) regulates insulin expression and secretion
from the β-cells in a glucose-dependent fashion; (2) stimulates the secretion of somatostatin;
and (3) suppresses the secretion of glucagon from the α cells. Although not formally
resolved, the strong glucagonostatic effect is presumed to result from one or all
of the following: (1) direct suppression by stimulation of GLP-1 receptors on a cells,
although this is unlikely; (2) paracrine suppression of glucagon secretion by intra-islet
release of somatostatin; or (3) paracrine suppression by intra-islet release of insulin.
Whatever the cellular mechanism, GLP-1 is unique in its capacity to simultaneously
stimulate insulin secretion and inhibit glucagon release. Although a therapeutic insulin
infusion also inhibits glucagon release, this affect is not as potent as that of GLP-1,
which exerts a direct, intra-islet paracrine inhibition of glucagon secretion.
[0026] The dual capacity of GLP-1 to powerfully stimulate insulin release and inhibit glucagon
secretion, together with the strict glucose-dependence of its insulinotropic action,
endow this molecule with a unique therapeutic potential in the management of ischemia-reperfusion.
First, GLP-1 strongly stimulates the secretion of endogenous insulin and therefore
can be used to achieve all of the beneficial actions attributed to an insulin infusion
in the metabolic treatment of ischemia reperfusion. Although high-dose GIK infusions
typically contain 25-33% glucose and 50-100 U insulin/L, the requirement for introduction
of hyperglycemia per se to achieve therapeutic efficacy, versus only providing a metabolic
milieu for the safe administration of high doses of insulin, is unclear. It is likely
that adequate blood glucose levels are required to enable substrate delivery, but
this does not necessarily imply a need for hyperglycemia and should not detract from
the fact that insulin exerts important effects other than glucose uptake.
[0027] Glucose is not required as a safety measure, since blood levels of ≤ 3.5 mM abrogate
the insulin-stimulating activity of GLP-1, thereby completely protecting against the
dangers of hypoglycemia.
[0028] Second, GLP-1 exerts a powerful glucagonostatic effect, which together with its insulinotropic
action will lead to a strong suppression of FFAs. One of the major benefits of glucose-insulin
infusions is the reduction in circulating FFA levels and the suppression of FFA uptake.
FFAs and their metabolites have direct toxic effects on the ischemic myocardium as
well as during the reperfusion period, when they contribute to stunning, and hence
reduction of FFA levels is a major therapeutic goal of metabolic intervention in ischemia-reperfusion,
goal of metabolic intervention in ischemia-reperfusion. As glucagon is a powerful
stimulus for adipose tissue lipolysis and FFA production, GLP-1 mediated glucagon
suppression further augments the insulin-induced reduction in circulating FFAs. Thus,
GLP-1 therapy is superior to a glucose-insulin infusion in this regard. Indeed, preliminary
data in healthy volunteers indicate that an intravenous GLP-1 infusion will reduce
fasting plasma FFA levels to <10% of control values.
[0029] GLP-1 should be effective in the majority of patients without requiring concurrent
glucose administration.
[0030] In addition, it also may be necessary to administer potassium to correct excess shifts
of potassium in the intracellular compartment.
[0031] In addition to GLP-1 or its biological analogues, the therapy can include use of
free radical scavengers such as glutathione, melatonin, Vitamin E, and superoxide
dismutase (SOD). In such combinations reperfusion damage risk is lessened even further.
[0032] The term "GLP-1", or glucagon-like peptide, includes mimetics, and as used in the
context of the present invention can be comprised of glucagon-like peptides and related
peptides and analogs of glucagon-like peptide-1 that bind to a glucagon-like peptide-1
(GLP-1) receptor protein such as the GLP-1 (7-36) amide receptor protein and has a
corresponding biological effect on insulin secretion as GLP-1 (7-36) amide, which
is a native, biologically active form of GLP-1, See Goke, B and Byrne, M,
Diabetic Medicine, 1996, 13:854-860. The GLP-1 receptors are cell-surface proteins found, for example,
on insulin-producing pancreatic β-cells. Glucagon-like peptides and analogs will include
species having insulinotropic activity and that are agonists of,
i.e. activate, the GLP-1 receptor molecule and its second messenger activity on,
inter alia, insulin producing β-cells. Agonists of glucagon-like peptide that exhibit activity
through this receptor have been described: EP 0708179A2; Hjorth, S.A.
et al., J. Biol. Chem. 269 (48):30121-30124 (1994); Siegel, E.G. et al. Amer. Diabetes Assoc. 57th Scientific
Sessions, Boston (1997); Hareter, A. et al. Amer. Diabetes Assoc. 57th Scientific
Sessions, Boston (1997); Adelhorst, K. et al.
J. Biol. Chem. 269(9):6275-6278 (1994); Deacon C.F. et al. 16th International Diabetes Federation
Congress Abstracts,
Diabetologia Supplement (1997); Irwin, D.M. et al.,
Proc. Natl. Acad. Sci. USA. 94:7915-7920 (1997); Mosjov, S.,
Int. J. Peptide Protein Res. 40:333-343 (1992). Glucagon-like molecules include polynucleotides that express agonists
of GLP-1, i.e. activators of the GLP-1 receptor molecule and its secondary messenger
activity found on,
inter alia, insulin-producing β-cells. GLP-1 mimetics that also are agonists include, for example,
chemical compounds specifically designed to activate the GLP-1 receptor. Glucagon-like
peptide-1 antagonists are also known, for example see e.g. Watanabe, Y et al.,
J. Endocrinol. 140(1):45-52 (1994), and include exendin (9-39) amine, an exendin analog, which is
a potent antagonist of GLP-1 receptors (see, e.g. WO97/46584 Recent publications disclose
Black Widow GLP-1 and Ser
2 GLP-1, see G.G. Holz, J.F. Hakner/
Comparative Biochemistry and Physiology, Part B 121(1998)177-184 and Ritzel, et al.,
A synthetic glucagon-like peptide-1 analog with improved plasma stability, J.Endocrinol 1998 Oct. 159(1):93-102.
[0033] Further embodiments include chemically synthesized glucagon-like polypeptides as
well as any polypeptides or fragments thereof which are substantially homologous.
"Substantially homologous," which can refer both to nucleic acid and amino acid sequences,
means that a particular subject sequence, for example, a mutant sequence, varies from
a reference sequence by one or more substitutions, deletions, or additions, the net
effect of which does not result in an adverse functional dissimilarity between reference
and subject sequences. For purposes of the present invention, sequences having greater
than 50 percent homology, and preferably greater than 90 percent homology, equivalent
biological activity in enhancing β-cell responses to plasma glucose levels, and equivalent
expression characteristics are considered substantially homologous. For purposes of
determining homology, truncation of the mature sequence should be disregarded. Sequences
having lesser degrees of homology, comparable bioactivity, and equivalent expression
characteristics are considered equivalents.
[0034] Mammalian GLP peptides and glucagon are encoded by the same gene. In the ileum the
phenotype is processed into two major classes of GLP peptide hormones, namely GLP-1
and GLP-2. There are four GLP-1 related peptides known which are processed from the
phenotypic peptides. GLP-1 (1-37) has the sequence His Asp Glu Phe Glu Arg His Ala
Glu Gly Thr Phe Thr Ser Asp Val Ser Ser Tyr Leu Glu Gly Gln Ala Ala Lys Glu Phe Ile
Ala Trp Leu Val Lys Gly Arg Gly (SEQ. ID NO:1). GLP-1 (1-37) is amidated by post-translational
processing to yield GLP-1 (1-36) NH
2 which has the sequence His Asp Glu Phe Glu Arg His Ala Glu Gly Thr Phe Thr Ser Asp
Val Ser Ser Tyr Leu Glu Gly Gin Ala Ala Lys Glu Phe Ile Ala Trp Leu Val Lys Gly Arg
(NH
2) (SEQ. ID NO:2); or is enzymatically processed to yield GLP-1 (7-37) which has the
sequence His Ala Glu Gly Thr Phe Thr Ser Asp Val Ser Ser Tyr Leu Glu Gly Gln Ala Ala
Lys Glu Phe Ile Ala Trp Leu Val Lys Gly Arg Gly (SEQ. ID NO:3). GLP-1 (7-37) can also
be amidated to yield GLP-1 (7-36) amide which is the natural form of the GLP-1 molecule,
and which has the sequence His Ala Glu Gly Thr Phe Thr Ser Asp Val Ser Ser Tyr Leu
Glu Gly Gin Ala Ala Lys Glu Phe Ile Ala Trp Leu Val Lys Gly Arg (NH
2) (SEQ. ID NO:4) and in the natural form of the GLP-1 molecule.
[0035] Intestinal L cells secrete GLP-1 (7-37) (SEQ. ID NO:3) and GLP-1 (7-36) NH
2 (SEQ. ID NO:4) in a ratio of 1 to 5, respectively. These truncated forms of GLP-1
have short half-lives
in situ, i.e., less than 10 minutes, and are inactivated by an aminodipeptidase IV to yield
Glu Gly Thr Phe Thr Ser Asp Val Ser Ser Tyr Leu Glu Gly Gln Ala Ala Lys Glu Phe Ile
Ala Trp Leu Val Lys Gly Arg Gly (SEQ. ID NO:5); and Glu Gly Thr Phe Thr Ser Asp Val
Ser Ser Tyr Leu Glu Gly Gln Ala Ala Lys Glu Phe Ile Ala Trp Leu Val Lys Gly Arg (NH
2) (SEQ. ID NO:6), respectively. The peptides Glu Gly Thr Phe Thr Ser Asp Val Ser Ser
Tyr Leu Glu Gly Gln Ala Ala Lys Glu Phe Ile Ala Trp Leu Val Lys Gly Arg Gly (SEQ.
ID NO:5) and Glu Gly Thr Phe Thr Ser Asp Val Ser Ser Tyr Leu Glu Gly Gln Ala Ala Lys
Glu Phe Ile Ala Trp Leu Val Lys Gly Arg (NH
2) (SEQ. ID NO:6), have been speculated to affect hepatic glucose production, but do
not stimulate the production or release of insulin from the pancreas.
[0036] There are six peptides in Gila monster venoms that are homologous to GLP-1. Their
sequences are compared to the sequence of GLP-1 in Table 1.
[0037] The major homologies as indicated by the outlined areas in Table 1 are: peptides
c and h are derived from b and g, respectively. All 6 naturally occurring peptides
(a, b, d, e, f and g) are homologous in positions 1, 7, 11 and 18. GLP-1 and exendins
3 and 4 (a, b and d) are further homologous in positions 4, 5, 6, 8, 9, 15, 22, 23,
25, 26 and 29. In position 2, A, S and G are structurally similar. In position 3,
residues D and E (Asp and Glu) are structurally similar. In positions 22 and 23 F
(Phe) and I (Ile) are structurally similar to Y (Tyr) and L (Leu), respectively. Likewise,
in position 26 L and I are structurally equivalent.
[0038] Thus, of the 30 residues of GLP-1, exendins 3 and 4 are identical in 15 positions
and equivalent in 5 additional positions. The only positions where radical structural
changes are evident are at residues 16, 17, 19, 21, 24, 27, 28 and 30. Exendins also
have 9 extra residues at the carboxyl terminus.
[0039] The GLP-1 like peptides can be made by solid state chemical peptide synthesis. GLP-1
can also be made by conventional recombinant techniques using standard procedures
described in, for example, Sambrook and Maniaitis. "Recombinant," as used herein,
means that a protein is derived from recombinant (e.g., microbial or mammalian) expression
systems which can be genetically modified to contain an expression gene for GLP-1
or its biologically active analogues.
[0040] The GLP-1 like peptides can be recovered and purified from recombinant cell cultures
by methods including, but not limited to, ammonium sulfate or ethanol) precipitation,
acid extraction, anion or cation exchange chromatography, phosphocellulose chromatography,
hydrophobic interaction chromatography, affinity chromatography, hydroxylapatite chromatography
and lectin chromatography. High performance liquid chromatography (HPLC) can be employed
for final purification steps.
[0041] The polypeptides of the present invention may be a naturally purified product, or
a product of chemical synthetic procedures, or produced by recombinant techniques
from prokaryotic or eukaryotic hosts (for example by bacteria, yeast, higher plant,
insect and mammalian cells in culture or
in vivo). Depending on the host employed in a recombinant production procedure, the polypeptides
of the present invention are generally non-glycosylated, but may be glycosylated.
[0042] GLP-1 activity can be determined by standard methods, in general, by receptor-binding
activity screening procedures which involve providing appropriate cells that express
the GLP-1 receptor on their surface, for example, insulinoma cell lines such as RINmSF
cells or INS-1 cells. See also Mosjov, S.(1992) and EP0708170A2. In addition to measuring
specific binding of tracer to membrane using radioimmunoassay methods, cAMP activity
or glucose dependent insulin production can also be measured. In one method, a polynucleotide
encoding the receptor of the present invention is employed to transfect cells to thereby
express the GLP-1 receptor protein. Thus, for example, these methods may be employed
for screening for a receptor agonist by contacting such cells with compounds to be
screened and determining whether such compounds generate a signal, i.e. activate the
receptor.
[0043] Polyclonal and monoclonal antibodies can be utilized to detect, purify and identify
GLP-1 like peptides for use in the methods described herein. Antibodies such as ABGA1178
detect intact unspliced GLP-1 (1-37) or N-terminally-truncated GLP-1 (7-37) or (7-36)
amide. Other antibodies detect on the very end of the C-terminus of the precursor
molecule, a procedure which allows by subtraction to calculate the amount of biologically
active truncated peptide, i.e. GLP-1 (7-37) or (7-36) amide (Orskov et al. Diabetes,
1993, 42:658-661; Orskov et al. J. Clin. Invest. 1991, 87:415-423).
[0044] Other screening techniques include the use of cells which express the GLP-1 receptor,
for example, transfected CHO cells, in a system which measures extracellular pH or
ionic changes caused by receptor activation. For example, potential agonists may be
contacted with a cell which expresses the GLP-1 protein receptor and a second messenger
response, e.g. signal transduction or ionic or pH changes, may be measured to determine
whether the potential agonist is effective.
[0045] The glucagon-like peptide-1 receptor binding proteins of the present invention may
be used in combination with a suitable pharmaceutical carrier. Such compositions comprise
a therapeutically effective amount of the polypeptide, and a pharmaceutically acceptable
carrier or excipient. Such a carrier includes, but is not limited to, saline, buffered
saline, dextrose, water, glycerol, ethanol, lactose, phosphate, mannitol, arginine,
trehalose and combinations thereof. The formulations should suit the mode of administration
and are readily ascertained by those of skill in the art. The GLP-1 peptide may also
be used in combination with agents known in the art that enhance the half-life in
vivo of the peptide in order to enhance or prolong the biological activity of the peptide.
For example, a molecule or chemical moiety may be covalently linked to the composition
of the present invention before administration thereof. Alternatively, the enhancing
agent may be administered concurrently with the composition. Still further, the agent
may comprise a molecule that is known to inhibit the enzymatic degradation of GLP-1
like peptides may be administered concurrently with or after administration of the
GLP-1 peptide composition. Such a molecule may be administered, for example, orally
or by injection.
[0046] Patients administered GLP-1 or its analogues in combination with the carrier systems
here enumerated, especially those treated before a planned event or within the first
4 hours after an ischemic event, are observed to have less arrhythmia, less tissue
damage, and less discomfort without side effects.
[0047] From these considerations it is evident that an infusion of GLP-1 can be expected
to exert a major therapeutic effect in myocardial reperfusion. It is expected that
GLP-1 can be administered either by I.V. or subcutaneous administration for continuous
infusion by intravenous (I.V.)0.1 pmol/kg/min to 10 pmol/kg/min and by subcutaneous
(S.C.) 0.1 pmol/kg/min to 75 pmol/kg/min, and for single injection (bolus) by LV.
0.005 nmol/kg to 20 nmol/kg and S.C. 0.1 nmol/kg to 100 nmol/kg are suitable levels
of administration. The GLP-1 infusion can be coadministered with glucose (5%) if required
to maintain blood glucose levels ≥ 5 mM (to maintain efficient insulin secretion).
Similarly, coadministration of potassium (K
+) will also be considered, depending on the extent to which activation of the membrane
Na
+/K
+ ATPase leads to a shift of K
+ into the intracellular space. The GLP-1 treatment will be commenced as early in the
post-ischemic period as possible after, for example, acute spontaneous ischemia in
the home or ambulance context and before reperfusion therapies, and continued thereafter.
In the case of cardiac surgery, the GLP-1 infusion should commence 12-24 hours prior
to surgery, during surgery from the onset of anesthesia until aortic crossclamping,
and immediately after unclamping for a period of at least 72 hours postoperatively.
As earlier explained, co-administration of a free radical scavenger will further aid
reperfusion recovery.
[0048] From the above it can be seen that the invention accomplishes all of its stated objectives.
1. Use of a composition which includes GLP-1, or a biologically active analogue thereof,
and a pharmaceutically acceptable carrier, for the manufacture of a medicament for
treating individuals in need of amelioration or organ tissue injury caused by reperfusion
of blood flow following a period of ischemia, said treatment does not include the
co-administration of glucose.
2. Use of a composition according to claim 1 wherein the pharmaceutical carrier is selected
from the group consisting of saline, buffered saline, water, glycerol, ethanol, lactose,
phosphate, mannitol, arginine, trehalose, and combinations thereof.
3. Use of a composition according to claim 1 or 2, wherein the composition is to be administered
at a dose level of GLP-1 of 0.1 pmol/kg/min. to 10 pmol/min.
4. Use of a composition according to any of the preceding claims, wherein concurrent
administration of a free radical scavenger is to be effected.
5. Use of a composition according to any of the preceding claims, wherein administration
is to commence within 4 hours of an ischemic event.
6. Use of a composition according to claim 5, wherein administration is to be effected
within 4 hours of an ischemic event and continues thereafter.
7. Use of a composition according to any of the preceding claims, wherein administration
is to be effected intravenously.
8. Use of a composition according to any of claims 1 to 7, wherein administration is
to be effected by subcutaneous or micropressure injection, deep lung insufflation,
external or implant pump, depot injection, and other sustained release mechanisms,
oral delivery and patch, buccal and other cross skin and membrane mechanisms.
9. Use of a composition according to any of the preceding claims, wherein the organ tissue
is the myocardium.
10. Use of a composition according to any of the preceding claims, wherein the need for
amelioration of tissue damage by metabolic intervention arises from a medical procedure
that is a surgical event selected from the group consisting of cardiac surgical procedures,
organ transplants, traumatic limb amputation and reattachment.
11. Use of a composition according to any of the preceding claims, wherein the medical
procedure involves an ischemic reperfusion event, said event being concurrent with
gut infarct and myocardial infarct.
1. Verwendung einer Zusammensetzung, die GLP-1 oder ein biologisch aktives Analogon davon
und einen pharmazeutisch verträglichen Träger umfasst, zur Herstellung eines Medikaments
zur Behandlung von Individuen, bei denen eine Verbesserung einer Organgewebeverletzung
notwendig ist, welche durch Reperfusion eines Blutflusses verursacht wurde, die auf
eine Ischämieperiode folgte, wobei die Behandlung keine Co-Administration von Glucose
umfasst.
2. Verwendung einer Zusammensetzung nach Anspruch 1, wobei der pharmazeutische Träger
ausgewählt ist aus der Gruppe bestehend aus Kochsalzlösung, gepufferter Kochsalzlösung,
Dextrose, Wasser, Glyzerin, Ethanol, Lactose, Phosphat, Mannitol, Arginin, Trehalose
und Kombinationen davon.
3. Verwendung einer Zusammensetzung nach Anspruch 1 oder 2, wobei die Zusammensetzung
bei einer Dosiskonzentration von GLP-1 von 0,1 pmol/kg/min. bis 10 pmol/kg/min. zu
verabreichen ist.
4. Verwendung einer Zusammensetzung nach einem der vorhergehenden Ansprüche, wobei gleichzeitig
die Verabreichung eines Scavengers für freie Radikale erfolgt.
5. Verwendung einer Zusammensetzung nach einem der vorhergehenden Ansprüche, wobei die
Verabreichung innerhalb von vier Stunden nach einem ischämischen Ereignis beginnt.
6. Verwendung einer Zusammensetzung nach Anspruch 5, wobei die Verabreichung innerhalb
von vier Stunden nach einem ischämischen Ereignis erfolgt und danach fortgesetzt wird.
7. Verwendung einer Zusammensetzung nach einem der vorhergehenden Ansprüche, wobei die
Verabreichung intravenös erfolgt.
8. Verwendung einer Zusammensetzung nach einem der Ansprüche 1 - 7, wobei die Verabreichung
durch subkutane oder Mikrodruckinjektion, tiefe Lungeninsufflation, externe oder implantierte
Pumpen, Depotinjektion und andere Mechanismen mit verzögerter Freisetzung, oraler
Gabe und Pflaster, buccale und andere Mechanismen über die Haut und über Membranen
erfolgt.
9. Verwendung einer Zusammensetzung nach einem der vorhergehenden Ansprüche, wobei das
Organgewebe das Myocard ist.
10. Verwendung einer Zusammensetzung nach einem der vorhergehenden Ansprüche, wobei die
Notwendigkeit der Verbesserung einer Gewebeschädigung durch metabolische Intervention
durch eine medizinische Vorgehensweise entsteht, die ein chirurgischer Eingriff ist,
ausgewählt aus der Gruppe bestehend aus chirurgischem Vorgehen am Herzen, Organtransplantationen,
traumatischen Gliedmaßenamputationen und Wiederannähen.
11. Verwendung einer Zusammensetzung nach einem der vorhergehenden Ansprüche, wobei die
medizinische Vorgehensweise ein ischämisches Reperfusionsereignis umfasst und wobei
das Ereignis gleichzeitig mit Darminfarkt und Myocardinfarkt eintritt.
1. Utilisation d'une composition incluant du GLP-1, ou un analogue biologiquement actif
en dérivant, et un support pharmaceutiquement acceptable, pour la fabrication d'un
médicament pour le traitement d'individus ayant besoin d'amélioration des lésions
provoquées au tissu organique par des perfusions fréquentes des circuits sanguins
suite à une période d'ischémie, ledit traitement ne comprenant pas l'administration
simultanée de glucose.
2. Utilisation d'une composition selon la revendication 1, dans laquelle le support pharmaceutique
est choisi dans le groupe consistant en sels, tampons salins, dextrose, eau, glycérol,
éthanol, lactose, phosphates, mannitol, arginine, tréhalose et leurs combinaisons.
3. Utilisation d'une composition selon la revendication 1 ou 2, dans laquelle la composition
doit être administrée à une dose topique de GLP-1 de 0,1 µmol/kg/min à 10 µmol/kg/min.
4. Utilisation d'une composition selon l'une quelconque des revendications précédentes,
dans laquelle l'administration se fait concurremment avec celle d'un scavenger de
radicaux libres.
5. Utilisation d'une composition selon l'une quelconque des revendications précédentes,
dans laquelle l'administration est mise en oeuvre environ 4 heures avant l'incident
ischémique.
6. Utilisation d'une composition selon la revendication 5, dans laquelle l'administration
est mise en oeuvre environ 4 heures avant l'incident ischémique et se poursuit ensuite.
7. Utilisation d'une composition selon l'une quelconque des revendications précédentes,
dans laquelle l'administration est effectuée par voie intraveineuse.
8. Utilisation d'une composition selon l'une quelconque des revendications 1 à 7, dans
laquelle l'administration est effectuée par voie sous-cutanée ou par injection par
micropression, insufflation pulmonaire profonde, pompe implantée ou externe, injection
par dépôt, ou autres mécanismes à libération soutenue, application par voie orale
ou patch, et mécanismes membranaires, intradermique ou buccaux.
9. Utilisation d'une composition selon l'une quelconque des revendications précédentes,
dans laquelle le tissu organique est le myocarde.
10. Utilisation d'une composition selon l'une quelconque des revendications précédentes,
dans laquelle le besoin d'améliorer les lésions tissulaires résultant d'interventions
métaboliques répétées suite à un traitement médical, tel qu'une intervention chirurgicale
est choisi dans le groupe consistant en procédés de chirurgie cardiaque, de transplantations
d'organes, d'amputation d'un membre et de greffes.
11. Utilisation d'une composition selon l'une quelconque des revendications précédentes,
dans laquelle le traitement médical implique un incident dû à des reperfusions fréquentes
ischémiques, ledit incident étant simultané à un infarctus du myocarde ou à une lésion
intestinale.